Tactile sensation providing apparatus and control method for tactile sensation providing apparatus

ABSTRACT

A tactile sensation providing apparatus includes a touch sensor configured to detect a touch input, a load detection unit configured to detect a pressure load on a touch face of the touch sensor, a tactile sensation providing unit configured to vibrate the touch face, and a control unit configured to adjust a drive signal of the tactile sensation providing unit based on a pushed position when the pressure load detected by the load detection unit satisfies a standard to provide a tactile sensation.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation Application of U.S. patentapplication Ser. No. 13/392,855, filed Feb. 27, 2012, which is the U.S.National Phase of International Application No. PCT/JP2010/005186 filedAug. 23, 2010, which claims priority to and the benefit of JapanesePatent Application No. 2009-197444 filed Aug. 27, 2009 and JapanesePatent Application No. 2010-149063 filed Jun. 30, 2010, the entirecontents of which are incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to a tactile sensation providingapparatus having a touch sensor and a control method for a tactilesensation providing apparatus.

BACKGROUND ART

In recent years, input apparatuses having touch sensors such as touchpanels, touch switches or the like are popularly used as inputapparatuses such as operation units, switches and the like for receivinginput operations by a user in mobile terminals such as mobile phones,gaming machines, information equipments such as calculator, ticketvending machines, home electric appliances such as microwaves, TV sets,lighting equipments, industrial equipments (FA equipments) and the like.

There are known a variety of types of those touch sensors, such as aresistive film type, a capacitive type, an optical type and the like.However, touch sensors of these types receive a touch input by a fingeror a stylus pen and, unlike push-button switches, the touch sensorsthemselves are not physically displaced even when being touched.

Since the touch sensors are not physically displaced when touched, anoperator cannot obtain feedback to an input even when the touch input isreceived. As a result, the operator is likely to input erroneously bytouching the same spot multiple times, which may be stressful for theoperator.

As methods to prevent such repetitious inputs, there are known methodsof visually or auditory confirming the input operations by, for example,generating sounds or by changing a display state, such as colors ofinput objects such as input buttons and the like graphically depicted ona display unit, according to an input position upon reception of thetouch input.

However, such auditory feedback may be difficult to be confirmed in anoisy environment and is not applicable when the equipment being used isin a silent mode. In addition, in using such visual feedback, when theoperator is inputting by the finger, if the input object displayed onthe display unit is small, the operator may not be able to confirm thechange in the display state, as a view of the input object is blocked bya finger.

There is also suggested a feedback method relying on neither theauditory- nor visual sensation but instead generating a tactilesensation at operator's fingertip by vibrating the touch sensor when thetouch sensor receives an input (for example, see Patent Documents 1, 2).

As a method to provide a more detailed tactile sensation, in addition,there is known a feedback method to calculate a sliding speed of auser's finger and the like from a contact position on the touch sensorin order to generate a plurality of types of vibrations having vibrationtimes differing among users corresponding to the sliding speeds (forexample, see Patent Document 3).

RELATED ART DOCUMENTS Patent Documents

Patent Document 1: Japanese Patent Laid-Open No. 2003-288158

Patent Document 2: Japanese Patent Laid-Open No. 2008-130055

Patent Document 3: Japanese Patent No. 4046095 Specification

SUMMARY Technical Problem

The techniques disclosed in the above Patent Documents 1 and 2, however,merely vibrate the touch sensor when the touch sensor receives an input.Therefore, in using the input apparatus having the button switches suchas push-button switches (push-type button switches) are graphicallydepicted on the touch sensor, and, if the touch sensor has a lowthreshold to receive an input, a tactile sensation is provided when thefinger or the like lightly contacts (touches) the touch sensor. It maytrigger erroneous operations in response to an unintentional motion(touch) before the operator pushes, and inflict a feeling of strangenesson the operator upon the unintentional motion (touch). Here, thethreshold for the touch sensor to receive the touch input is a thresholdat which the touch sensor responds, which is, for a touch sensor of theresistive film type, a threshold of a pressure at which an upperconductive film is contacted to a lower conductive film, and, for atouch sensor of the capacitive type, a threshold for detection of anelectric signal by contact.

In order to address such a disadvantage, the applicant has developed atactile sensation providing apparatus which detects a pressure load on atouch face of the touch sensor and, when the detected pressure loadreaches a predetermined threshold to provide the tactile sensation,vibrates the touch face of the touch sensor such that the tactilesensation is provided to a pressing object such as the finger and thelike.

According to this input apparatus, since the tactile sensation isprovided when the operator pushes the touch face and the pressure loadreaches the predetermined threshold, it is possible to allow theoperator to perceive reception of an input while reliably preventingerroneous operations triggered by an unintentional touch as describedabove and the feeling of strangeness.

The technique disclosed in Patent Document 3 set forth above does nottake into account a change in a vibration amount of the touch facecorresponding to a position on the touch face in providing the tactilesensation to the user. As a result of earnest investigations and studieson the change in the vibration amount of the touch face corresponding tothe position on the touch face, the inventor obtained expertise asfollows. FIG. 7 is a diagram illustrating an example of an arrangementof vibration elements on the touch face of the touch sensor, and FIG. 8is a diagram illustrating a distribution of the vibration amount by apredetermined drive voltage when the vibration elements are arranged asillustrated in FIG. 7. As illustrated in FIG. 8, when each of thevibration elements illustrated in FIG. 7 is vibrated by thepredetermined drive voltage (for example, 1 V), the vibration amount ofthe touch face takes a different value depending on a pushed position onthe touch face. In an example illustrated in FIG. 8, the vibrationamounts (amplitude) of positions A, B and C are 20 μm, 15 μm and 17 μm,respectively. A number of factors including attenuation of vibration inaccordance with a distance from the vibration element and influence of areflected wave may be considered as reasons for difference in thevibration amount depending on the position on the touch face. Such adifference in amplitude of vibration of the touch face has a greatimpact on the tactile sensation the user feels.

Since the technique disclosed in Patent Document 3 does not take intoaccount the change in the vibration amount of the touch face dependingon the position on the touch face as described above, the vibrationelement is driven by the same drive signal in response to the same inputoperation by the user (for example, motion with the same sliding speed),regardless of the position of the input on the touch face by the user.In this case, however, since the amplitude of vibration of the touchface differs depending on the position on the touch face, the user feelsa different tactile sensation at each position. That is, the user havean increased feeling of strangeness in operation as obtaining differenttactile sensations at different positions on the touch face in responseto the same input operation. In order to improve an operation sensationof the user, it is preferable to provide the same tactile sensation tothe user, regardless of the position of the input.

An object of the present disclosure, in order to meet such arequirement, is to provide the tactile sensation providing apparatus andmethods for providing the constant tactile sensation to the user,regardless of a position of an input by the user.

Solution to Problem

In order to achieve the above object, the present disclosure providesthe following:

A tactile sensation providing apparatus according to the presentdisclosure comprises a touch sensor configured to detect a touch input,a load detection unit configured to detect a pressure load on a touchface of the touch sensor, a tactile sensation providing unit configuredto vibrate the touch face, and a control unit configured to adjust adrive signal of the tactile sensation providing unit based on a pushedposition when the pressure load detected by the load detection unitsatisfies a standard to provide a tactile sensation.

A control method according to the present disclosure, for a tactilesensation providing apparatus including a touch sensor configured todetect a touch input, a load detection unit configured to detect apressure load on a touch face of the touch sensor, and a tactilesensation providing unit configured to vibrate the touch face, thecontrol method, comprises adjusting a drive signal of the tactilesensation providing unit based on a pushed position when the pressureload detected by the load detection unit satisfies a standard to providea tactile sensation.

A tactile sensation providing apparatus according to the presentdisclosure comprises a touch sensor configured to detect a touch input,a piezoelectric element mounted on the touch sensor, and a control unitconfigured to detect a pressure load on a touch face of the touch sensorbased on an output signal of the piezoelectric element. When thepressure load detected satisfies a standard to provide a tactilesensation, the control unit is configured to adjust a drive signal ofthe piezoelectric element based on a pushed position.

A control method according to the present disclosure, for a tactilesensation providing apparatus including a touch sensor configured todetect a touch input, and a piezoelectric element mounted on the touchsensor, comprises detecting a pressure load on a touch face of the touchsensor based on an output signal of the piezoelectric element and, whenthe pressure load detected satisfies a standard to provide a tactilesensation, adjusting a drive signal of the piezoelectric element basedon a pushed position.

Effect of the Disclosure

The tactile sensation providing apparatus according to the presentdisclosure controls based on the pushed position of the pressing objectsuch as a user's finger and the like such that the tactile sensation isprovided to a user by the vibration with the certain amplitude. Thereby,a constant tactile sensation is provided to the user regardless of aposition of an input by the user.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a functional block diagram illustrating a tactile sensationproviding apparatus according to a first embodiment of the presentdisclosure;

FIGS. 2A and 2B illustrate diagrams illustrating an exemplary housingstructure of a part including a touch sensor illustrated in FIG. 1;

FIG. 3 is a flow chart illustrating an operation to provide a tactilesensation by the tactile sensation providing apparatus according to thefirst embodiment;

FIG. 4 is a functional block diagram illustrating a tactile sensationproviding apparatus according to a second embodiment of the presentdisclosure;

FIGS. 5A and 5B illustrate diagrams illustrating an exemplary housingstructure of a part including the touch sensor illustrated in FIG. 4;

FIG. 6 is a flow chart illustrating an operation to provide the tactilesensation by the tactile sensation providing apparatus according to thesecond embodiment;

FIG. 7 is a diagram illustrating an exemplary arrangement of vibrationelements on a touch face of the touch sensor;

FIG. 8 is a diagram illustrating a distribution of vibration amounts bya predetermined drive voltage with the vibration elements being arrangedas illustrated in FIG. 7;

FIG. 9 is a diagram illustrating a relationship between the drivevoltage and the vibration amount at each position with the vibrationelements being arranged as illustrated in FIG. 7;

FIG. 10 is a diagram illustrating an example of voltage adjustmentinformation set for each area on the touch face of the touch sensor;

FIG. 11 is a diagram illustrating an example of the voltage adjustmentinformation set for each area in a size corresponding to its position onthe touch face;

FIG. 12 is a diagram illustrating an example of the voltage adjustmentinformation set for each area in a size corresponding to its position onthe touch face;

FIG. 13 is a diagram illustrating an example of the voltage adjustmentinformation set for each area in a size corresponding to its position onthe touch face; and

FIG. 14 is a diagram illustrating an example of the voltage adjustmentinformation set for each area in a size corresponding to its position onthe touch face.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present disclosure will be described with referenceto the accompanying drawings.

First Embodiment

FIG. 1 is a functional block diagram illustrating a tactile sensationproviding apparatus according to a first embodiment of the presentdisclosure. This tactile sensation providing apparatus has a touchsensor 11, a load detection unit 12, a tactile sensation providing unit13, a display unit 14, a memory unit 15, and a control unit 16 tocontrol overall operations.

The touch sensor 11, disposed on the display unit 14, detects a touchinput to a touch face by a touch object such as a finger and the likeand may be of a known type, such as a resistive film type, a capacitivetype, an optical type and the like to output two-dimensional positioninformation of a touch position (pushed position of a pressing objectsuch as the finger and the like). The load detection unit 12 detects apressure load on the touch face of the touch sensor 11 by the pressingobject such as the finger and the like and may be, for example, a straingauge sensor, a piezoelectric element and the like, which linearly reactto the load. The tactile sensation providing unit 13 vibrates the touchsensor 11 and may be, for example, the piezoelectric element.

The display unit 14 displays an input object of an input button and thelike such as a push-button switch (push-type button switch) andconstituted by using, for example, a liquid crystal display panel, anorganic EL display panel and the like. The touch input to the inputobject displayed on the display unit 14 is detected by the control unit16 based on the position information output from the touch sensor 11.The memory unit 15 stores various information such as drive signalinformation of the tactile sensation providing unit 13 and driveadjustment information to adjust a drive signal based on the pushedposition of the pressing object and may be configured by using, forexample, a volatile memory or a nonvolatile memory. The control unit 16may include, for example, a CPU and the like and controls drive of thetactile sensation providing unit 13 based on information with respect tothe pushed position of the pressing object from the touch sensor 11,pressure load information from the load detection unit 12, and the drivesignal information and the drive adjustment information stored in thememory unit 15.

The drive signal information of the tactile sensation providing unit 13stored in the memory unit 15 includes various information such as afrequency and the number of vibration periods to vibrate the touch facefor each tactile sensation to be provided to a user. The control unit 16controls drive of the tactile sensation providing unit 13 based on thedrive signal information stored in the memory unit 15, and provides thepressing object such as the finger and the like with various tactilesensations such as, for example, a “throbbing” sensation, a “vibrating”sensation and a “plock” sensation. Here, when the tactile sensationproviding unit 13 is a piezoelectric element, in order to provide softtactile sensations such as, for example, the “throbbing” sensation andthe “vibrating” sensation, the control unit 16 applies a drive signal, atriangle wave or a sine wave with a frequency of approximately 200 Hz to500 Hz, for two or three periods to the piezoelectric element. In orderto provide a hard tactile sensation such as the “plock” sensation, thecontrol unit 16 applies a drive signal, a square wave with a frequencyof approximately 200 Hz to 500 Hz, for two or three periods to thepiezoelectric element.

In order to enhance an operation sensation of the user, in addition, thecontrol unit 16 can control drive of the tactile sensation providingunit 13 such that a click sensation such as a “ticking” sensation isprovided to the pressing object such as the finger and the like. Inorder to provide the click sensation such as the “ticking” sensationobtained when pressing a hard-type push-button switch, the control unit16 applies the drive signal, a sine wave or a square wave with afrequency of approximately 100 Hz to 200 Hz, for one period. With theclick sensation such as the “ticking” sensation, the user can obtain thetactile sensation similar to that obtained when pressing the actualpush-button switch even when inputting to the input object graphicallydepicted on the display unit 14. Therefore, the operation sensation ofthe user is improved.

The drive adjustment information stored in the memory unit 15 foradjustment of the drive signal based on the pushed position of thepressing object includes various information such as voltage adjustmentinformation for adjustment of voltage to apply to the tactile sensationproviding unit 13 and phase adjustment information for adjustment of aphase of vibration between vibration elements.

Voltage Adjustment Information

FIG. 9 is a diagram illustrating a relationship between the drivevoltage and a vibration amount at each position having the vibrationelements arranged as illustrated in FIG. 7. In a case illustrated inFIG. 9, in order to generate vibration with certain amplitude X (μm) atpositions A, B and C, necessary drive voltages are 0.5 V, 1.0 V and 2.0V, respectively. As such, it is considered that the relationship betweenpositions on the touch face of the touch sensor 11 and necessary drivevoltages to generate vibration with predetermined amplitude as describedabove is preliminarily measured and stored as a table or a list in thememory unit 15 at shipment of products. For example, the touch face ofthe touch sensor 11 is divided into m′n areas having m areas in avertical direction and m areas in a lateral direction, and therelationship between the amplitude and the drive voltage for each of theareas is stored in the memory unit 15. With such voltage adjustmentinformation, the control unit 16, in order to generate vibration withthe predetermined amplitude, adjusts the drive voltage based on thepushing position of the pressing object (pressing means) by, forexample, increasing to double (for example, 2.0 V) of a standard drivevoltage of the drive signal (for example, 1.0 V) or by reducing to half(for example, 0.5 V) of the standard voltage.

FIG. 10 is a diagram illustrating an example of the voltage adjustmentinformation set for each of the areas of the touch face 11 a of thetouch sensor 11. In this example, the touch sensor 11 is supported bysupport members made of elastic members at four corners and twovibration elements (for example, piezoelectric elements) are arranged atcenters of two opposing peripheries of the touch sensor 11. In addition,voltage adjustment coefficients (1-8) for the standard drive voltage areset as the voltage adjustment information for each of the areas of thetouch face 11 a. It is to be noted that the numbers of the voltageadjustment coefficients indicate not absolute intensities but relativeintensities among the voltage adjustment coefficients.

In the example in FIG. 10, relatively high voltage adjustmentcoefficients are set for areas near the support members, whereasrelatively low voltage adjustment coefficients are set for central areasof the touch face 11 a distant from the support members. This isbecause, when the vibration elements are vibrated by a typical drivevoltage, the areas of the touch face 11 a near the support members havesmall vibration amounts, whereas the central of the touch face 11 a havelarge vibration amounts. In the example illustrated in FIG. 10, inaddition, the voltage adjustment coefficients of the areas near thesupport members are finely changed, while those of the central areas ofthe touch face 11 a distant from the support members are less changed.This is because, when the vibration elements are vibrated by a typicaldrive voltage, the vibration amounts of the touch face 11 asignificantly differ among the positions of the areas near the supportmembers, whereas the vibration amounts of the touch face 11 a differ bysmall amounts among the positions of areas near the center of the touchface 11 a distant from the support members.

In the example in FIG. 10, in addition, comparing areas near the centersof the peripheries, for example, relatively small voltage adjustmentcoefficients are set for the areas near the centers of the peripherieshaving the vibration elements disposed thereon, whereas relatively largevoltage adjustment coefficients are set for the areas near the centersof the peripheries without the vibration elements. This is because, whenthe vibration elements are vibrated by a typical drive voltage, theperipheries having the vibration elements disposed thereon have largevibration amounts of the touch face 11 a, while the peripheries withoutthe vibration elements have small vibration amounts of the touch face 11a. In the example in FIG. 10, further, the voltage adjustmentcoefficients are changed by small amounts in the areas near the centersof the peripheries having the vibration elements disposed thereon, whilethe voltage adjustment coefficients are finely changed in the areas nearthe centers of the peripheries without the vibration elements. This isbecause, when the vibration elements are vibrated by a typical drivevoltage, the vibration amounts of the touch face 11 a differ by smallamounts among the areas near the centers of the peripheries having thevibration elements disposed thereon, whereas the vibration amounts ofthe touch face 11 a significantly differ among the areas near thecenters of the peripheries without the vibration elements.

Here, the areas to be set with the voltage adjustment coefficients donot necessarily have to be in the same size. FIG. 11 is a diagramillustrating an example of the voltage adjustment information set foreach of the areas in sizes according to their positions on the touchface 11 a. In FIG. 11, the areas near the support members are set inrelatively small sizes, whereas the areas near the center of the touchface 11 a distant from the support members are set in relatively largesizes. This is because, as described with reference to FIG. 10, thevoltage adjustment coefficients are to be finely changed among the areasnear the support members, while the voltage adjustment coefficients arenot to be finely changed among the areas near the center of the touchface 11 a distant from the support members. As with in a comparison ofthe areas near the centers of the peripheries, relatively small voltageadjustment coefficients are set for the areas near the centers of theperipheries having the vibration elements disposed thereon, whereasrelatively large voltage adjustment coefficients are set for the areasnear the centers of the peripheries without the vibration element. Thisis because, as described with reference to FIG. 10, when the vibrationelements are vibrated by a typical drive voltage, the peripheries of thetouch face 11 a having the vibration elements disposed thereon havelarge vibration amounts, while the peripheries of the touch face 11 awithout the vibration elements have small vibration amounts. Anappropriate voltage adjustment is enabled, even if there are a smallnumber of areas, by setting the voltage adjustment information for eachof the areas in sizes according to their positions on the touch face 11a as illustrated in FIG. 11.

FIG. 12 is a diagram illustrating another example of the voltageadjustment information set for each of the areas in sizes according totheir positions on the touch face 11 a. In FIG. 12, the touch face 11 ais divided into areas in a direction (vertical direction) of theperipheries having the vibration elements disposed thereon, and thoseareas are smaller in size as closer to the support members. In FIG. 12,in addition, the touch face 11 a is not divided in a direction (lateraldirection) of the peripheries without the vibration elements. Asdescribed with reference to FIG. 10, when the vibration elements arevibrated by a typical drive voltage, the areas of the touch face 11 anear the vibration elements have relatively large vibration amounts.Therefore, the areas distant from the central of the touch face 11 ahave relatively small attenuation of the vibration amounts. Taking thepositions of the vibration elements in consideration, the touch face 11a may be divided into areas in the direction (vertical direction) of theperipheries having the vibration elements disposed thereon, withoutdividing the touch face 11 a into areas in the direction (lateraldirection) of the peripheries without the vibration elements. It isenabled to appropriately adjust the voltage, even if there are only asmall number of areas, by dividing the touch face 11 a, as illustratedin FIG. 12, based on the positions of the vibration elements and settingthe voltage adjustment information for each of the areas in sizescorresponding to their positions on the touch face 11 a.

FIG. 13 is a diagram illustrating an example of the voltage adjustmentinformation set for each of the areas. In FIG. 13, the touch sensor 11is supported by six support members made of the elastic members intotal; at four corners, a center of a left periphery and a center of aright periphery. Two piezoelectric elements serving as the vibrationelements are disposed on the center of opposing peripheries of the touchsensor 11. In FIG. 13, in the similar manner to FIG. 12, the touch face11 a is divided into areas in the direction (lateral direction) of theperipheries having the vibration elements disposed thereon and the areasare smaller as closer to the support members. In addition, FIG. 14 is adiagram illustrating another example of the voltage adjustmentinformation set for each of the areas. In FIG. 14, the touch face 11 ais divided into relatively small areas near the six support members,while the touch face 11 a is divided into relatively large areas nearthe center of the touch face 11 a distant from the support members. Theareas to set the voltage adjustment coefficients do not need to bedivided in a matrix form. As with the area at the center of the touchface 11 a having a voltage adjustment coefficient “1” set thereto, it isenabled to diversify division of the areas to set the voltage adjustmentcoefficients. Thereby, more appropriate adjustment of the voltage isenabled.

Phase Adjustment Information

Also, with the vibration elements arranged as illustrated in FIG. 7,controlling the amplitude of each position is enabled by synthesizingthe vibrations of the vibration elements, that is, by forming asynthesized wave consisting of a plurality of vibrations. For example,it is assumed that, in order to generate a synthesized wave havingvibration with the certain amplitude x (μm) at the positions A, B and C,it is necessary to set a phase difference of the vibrations between twovibration elements illustrated in FIG. 7 to be π/4, 0 and 3π/4,respectively. In this case, a relationship between the positions on thetouch face of the touch sensor 11 and the phase difference necessary togenerate the vibration with predetermined amplitude is preliminarilymeasured and stored as a table or a list in the memory unit 15 atshipment of the products. For example, the touch face of the touchsensor 11 may be divided into m′n areas consisting of m areas in thevertical direction and n areas in the lateral direction, and therelationship between the amplitude and the phase difference for each ofthe areas is stored in the memory unit 15. In order to generate thevibration with the predetermined amplitude, the control unit 16 isenabled to adjust the phase of the drive signal based on such the phaseadjustment information, such as by setting the phase difference of thedrive signal applied to each of the tactile sensation providing units 13to be, for example, π/4 or 3π/4 of a standard phase difference (forexample, 0) based on the pushed position of the pressing object.

In the similar manner to the voltage adjustment coefficients illustratedin FIG. 11 to FIG. 14, the areas to set the phase adjustment informationdo not need to be in the same size. For example, the sizes of the areasto set the phase adjustment information may be determined based on theirpositions on the touch face. Also, the touch face may be divided intoareas to set the phase adjustment information based on a position of thevibration element.

It is to be noted that the drive adjustment information stored in thememory unit 15 to adjust the drive signal based on the pushed positionof the pressing object is not limited to the voltage adjustmentinformation for adjustment of the voltage to apply to the tactilesensation providing unit 13 and the phase adjustment information foradjustment of the phase of vibration between the vibration elements butmay take any parameters associated with adjustment of the drive signal,such as the frequency, the period and amplitude of the drive signal, anda current and a time to apply the drive signal, and the like.

FIGS. 2A and 2B illustrate an exemplary housing structure of a partincluding the touch sensor 11 illustrated in FIG. 1; FIG. 2A is across-sectional view of a main section, and FIG. 2B is a plane view ofthe main section. The display unit 14 is contained and held in a housing21. The touch sensor 11 is disposed on the display unit 14 viainsulators 22 made of elastic members. According to the presentembodiment, the touch sensor 11 and the display unit 14 are rectangularin shape in a planer view and the touch sensor 11 is disposed on thedisplay unit 14 via the insulators 22, which are arranged at the fourcorners outside a display area A of the display unit 14 illustrated by achain double-dashed line in FIG. 2B.

In addition, the housing 21 is provided with an upper cover 23 coveringa surface area of the touch sensor 11 outside the display area of thedisplay panel 14. Insulators 24 made of elastic members are arrangedbetween the upper cover 23 and the touch sensor 11.

The touch sensor 11 illustrated in FIGS. 2A and 2B may have, forexample, a surface member having the touch face 11 a and constituted bya transparent film or the glass, and a rear face member constituted bythe glass or acryl. The touch sensor 11 is designed such that, when thetouch face 11 a is pressed down, the pushed position or an entirestructure is bent (strained) slightly in accordance with a pressureforce.

A load sensor 31 having the strain gauge sensor or the piezoelectricelement to detect a load (pressuring force) applied on the touch sensor11 is provided, adhered or the like, on the surface of the touch sensor11 at a position close to each side covered by the upper cover 23. Inaddition, the piezoelectric element 32 to vibrate the touch sensor 11 isprovided, adhered or the like, on the rear face of the touch sensor 11close to each of two opposed sides. That is, the tactile sensationproviding apparatus illustrated in FIGS. 2A and 2B have the loaddetection unit 12 illustrated in FIG. 1 configured by using four straingauge sensors 31 and the tactile sensation providing unit 13 configuredby using two piezoelectric elements 32. The tactile sensation providingunit 13 vibrates the touch sensor 11 to vibrate the touch face 11 a suchthat the tactile sensation is provided to the touch object on the touchface 11 a. It is to be noted that the housing 21, the upper cover 23 andthe insulator 24 illustrated in FIG. 2A are omitted in FIG. 2B.

According to the tactile sensation providing apparatus of the presentembodiment, the touch sensor 11 detects a touch operation to the touchface 11 a. Then, the control unit 16 determines whether the pressureload detected by the load detection unit 12 satisfies a standard load(for example, 1.0 N) to provide the tactile sensation. When determiningthat the pressure load satisfies the standard to provide the tactilesensation, the control unit 16 controls drive of the tactile sensationproviding unit 13 based on the pushed position such that the tactilesensation is provided to the pressing object pressing the touch face 11a by vibration with the certain amplitude independent of the pushedposition.

The following is a description of an operation to provide the tactilesensation as notification information by the tactile sensation providingapparatus according to the present embodiment, with reference to aflowchart illustrated in FIG. 3.

First, the control unit 16 detects an input of the position information(pushed position of the pressing object) from the touch sensor 11 (stepS101) and detects contact to the touch face 11 a by the finger and thelike (step S102). Next, the control unit 16 determines whether thepressure load input from the load detection unit 12 satisfies thestandard load (1.0 N) to provide the tactile sensation (step S103). As aresult, when determining that the pressure load satisfies the standardload (Yes), the control unit 16, from the memory unit 15, retrieves thedrive signal information to provide the tactile sensation and the driveadjustment information corresponding to the position information fromthe touch sensor 11 (step S104). The control unit 16 adjusts the drivesignal information based on the drive adjustment information and drivesthe tactile sensation providing unit 13 with the adjusted drive signalsuch that the tactile sensation is provided to the user by the vibrationwith the certain amplitude independent of the pushed position of thepressing object (step S105). When the drive adjustment informationobtained at step S104 is adjustment information for the driving voltage,the control unit 16 adjusts the drive voltage of the drive signal anddrives the tactile sensation providing unit 13 such that the tactilesensation is provided to the user by the vibration with the certainamplitude. When the drive adjustment information obtained at step S104is adjustment information for the phase, the control unit 16 adjusts thephase of the drive signal and drives the tactile sensation providingunit 13 such that the tactile sensation is provided to the user by thevibration with the certain amplitude. Also, the control unit 16 maycontrol drive of the tactile sensation providing unit 13 such that theclick sensation is provided as the tactile sensation by the vibrationwith the certain amplitude.

According to the tactile sensation providing apparatus of the presentembodiment, when the user presses the touch face 11 a of the touchsensor 11 applying the pressure load satisfying the standard to providethe tactile sensation, the control unit 16 controls drive of the tactilesensation providing unit 13 based on the pushed position such that thetactile sensation is provided to the pressing object such as the fingerand the like by the vibration with the certain amplitude independent ofthe pushed position. Thereby, a constant tactile sensation is providedto the user regardless of the position of the input by the user, andthus the operation sensation of the user is improved.

In addition, the control unit 16 provides the tactile sensation by thevibration with the certain amplitude independent of the pushed positionto the pressing object such as the finger and the like by adjusting thevoltage to be applied to the tactile sensation providing unit 13 basedon the pushed position of the pressing object. That is, by adjusting thevoltage, a constant tactile sensation is provided to the user regardlessof the position of the input by the user, and thus the operationsensation of the user is improved.

Moreover, the control unit 16 provides the tactile sensation to thepressing object such as the finger and the like by the vibration withthe certain amplitude independent of the pushed position by adjustingthe phase of vibration of the tactile sensation providing unit 13 basedon the pushed position of the pressing object. That is, by adjusting thephase, a constant tactile sensation is provided to the user regardlessof the position of the input by the user, and thus the operationsensation of the user is improved.

Further, the control unit 16 controls drive of the tactile sensationproviding unit 13 such that the click sensation is provided as thetactile sensation with the certain amplitude. Accordingly, the user canobtain the tactile sensation similar to that obtained when pressing theactual button switch even when inputting to the input object graphicallydepicted on the display unit 14. Thereby, it is possible to furtherimprove the operation sensation of the user.

Second Embodiment

FIG. 4 is a functional block diagram illustrating a schematicconfiguration of a tactile sensation providing apparatus according to asecond embodiment of the present disclosure. This tactile sensationproviding apparatus has a configuration of that according to the firstembodiment illustrated in FIG. 1, except for having the piezoelectricelement 17 in place of the load detection unit 12 and the tactilesensation providing unit 13. The touch sensor 11, the display unit 14,the memory unit 15 and the control unit 16 have the same functions asthose of the first embodiment, and thus detailed descriptions thereofare omitted. According to the present embodiment, the “load detectionunit 12” and the “tactile sensation providing unit 13” in thedescriptions of the touch sensor 11, the display unit 14, the memoryunit 15 and the control unit 16 of the first embodiment are substitutedfor the “piezoelectric element 17”.

The piezoelectric element 17 is mounted on the touch sensor 11. Thecontrol unit 16 controls the piezoelectric element 17 to operate in oneof a load detection mode to detect the pressure load on the touch face11 a of the touch sensor 11 by utilizing direct piezoelectric effect anda tactile sensation providing mode to vibrate the touch face 11 a of thetouch sensor 11 by utilizing converse piezoelectric effect. In the loaddetection mode, an output signal corresponding to the pressure load onthe touch face 11 a of the touch sensor 11 is provided to the controlunit 16. In the tactile sensation providing mode, the touch face 11 a ofthe touch sensor 11 is vibrated based on the drive signal supplied fromthe control unit 16 such that a predetermined tactile sensationcorresponding to the drive signal is provided to the pressing objectpressing the touch face.

FIGS. 5A and 5B illustrate an exemplary housing structure of the touchsensor 11, the piezoelectric element 17 and the display unit 14illustrated in FIG. 4; FIG. 5A is a cross-sectional view of a mainsection, and FIG. 5B is a plane view of the main section. Thepiezoelectric element 17 is provided on the rear face of the touchsensor 11 at a position covered by the upper cover 23 and close to oneor a plurality of peripheries (here, for example, three peripheries), inorder to detect the pressure load on the touch face 11 a of the touchsensor 11 and also to vibrate the touch sensor 11 such that the tactilesensation is provided to the pressing object pressing the touch face 11a. The three piezoelectric elements 17 supply the outputs to the controlunit 16 in parallel. It is to be noted that the housing 21, the uppercover 23 and the insulator 24 illustrated in FIG. 5A are omitted in FIG.5B.

According to the tactile sensation providing apparatus of the presentembodiment, the touch sensor 11 detects the touch operation to the touchface 11 a. Then, the control unit 16 determines whether the pressureload detected by the piezoelectric element 17 satisfies the standardload (for example, 1.0 N) to provide the tactile sensation. Whendetermining that the pressure load satisfies the standard load toprovide the tactile sensation, the control unit 16 controls drive of thepiezoelectric element 17 based on the pushed position such that thetactile sensation is provided to the pressing object pressing the touchface 11 a by the vibration with the certain amplitude independent of thepushed position.

The following is a description of an operation to provide the tactilesensation as the notification information by the tactile sensationproviding apparatus according to the present embodiment, with referenceto a flowchart illustrated in FIG. 6.

First, the control unit 16 sets the three piezoelectric elements 17 inthe load detection mode and monitors outputs from them (step S201).Next, the control unit 16 detects an input of the position information(pushed position of the pressing object) from the touch sensor 11 (stepS202) and detects contact to the touch face 11 a by the finger and thelike (step S203). Then, the control unit 16 calculates the pressure loadon the touch sensor 11 based on the outputs of the three piezoelectricelements 17 and determines whether the pressure load satisfies thestandard (1.0 N) to provide the tactile sensation (step S204). As aresult, when determining that the pressure load satisfies the standardload (Yes), the control unit 16, referring to the memory unit 15,obtains the drive signal information to provide the tactile sensationand the drive adjustment information corresponding to the positioninformation from the touch sensor 11 (step S205). In addition, thecontrol unit 16 changes the mode of the three piezoelectric elements 17from the load detection mode to the tactile sensation providing mode(step S206). The control unit 16 adjusts the drive signal informationbased on the drive adjustment information and drives the piezoelectricelement 17 based on the adjusted drive signal such that the tactilesensation is provided to the user by the vibration with the certainamplitude (step S207). When the drive adjustment information obtained atstep S205 is the adjustment information for the drive voltage, thecontrol unit 16 adjusts the drive voltage of the drive signal and drivesthe piezoelectric element 17 such that the tactile sensation is providedto the user by the vibration with the certain amplitude. When the driveadjustment information obtained at step S205 is the adjustmentinformation for the phase, the control unit 16 adjusts the phase of thedrive signal and drives the piezoelectric element 17 such that thetactile sensation is provided to the user by the vibration with thecertain amplitude. Also, the control unit 16 can control drive of thepiezoelectric element 17 such that the click sensation is provided asthe tactile sensation by the vibration with the certain amplitude. Then,the control unit 16 sets the three piezoelectric elements 17 back in theload detection mode (step S208) and calculates the pressure load on thetouch sensor 11.

According to the tactile sensation providing apparatus of the presentembodiment, since the piezoelectric element 17 serves as a load sensorto detect the pressure load on the touch face 11 a of the touch sensor11 and as an actuator to vibrate the touch face 11 a, the number ofcomponents and cost are reduced. In addition, since the number of thecomponents can be reduced, space for the components is saved, anddownsizing of the apparatus is enabled.

According to the tactile sensation providing apparatus of the presentembodiment, in addition, when the user presses the touch face 11 a ofthe touch sensor 11 applying the pressure load satisfying the standardto provide the tactile sensation, the control unit 16 controls drive ofthe piezoelectric element 17 based on the pushed position such that thetactile sensation is provided to the pressing object such as the fingerand the like by the vibration with the certain amplitude independent ofthe pushed position. Thereby, a constant tactile sensation is providedto the user regardless of the position of the input by the user, and theoperation sensation of the user is improved.

In addition, the control unit 16 adjusts the voltage to be applied tothe piezoelectric element 17 based on the pushed position of thepressing object such that the tactile sensation is provided to thepressing object such as the finger and the like by the vibration withthe certain amplitude independent of the pushed position. That is, byadjusting the voltage, a constant tactile sensation is provided to theuser regardless of the position of the input by the user, and theoperation sensation of the user is improved.

Moreover, the control unit 16 adjusts the phase of vibration of thepiezoelectric element 17 based on the pushed position of the pressingobject such that the tactile sensation is provided to the pressingobject such as the finger and the like by the vibration with the certainamplitude independent of the pushed position. That is, by adjusting thephase, a constant tactile sensation is provided to the user regardlessof the position of the input by the user, and the operation sensation ofthe user is improved.

Further, the control unit 16 controls drive of the piezoelectric element17 to provide the click sensation as the tactile sensation with thecertain amplitude. Accordingly, the user obtains the tactile sensationsimilar to that obtained when pressing the actual button switch evenwhen inputting to the input object graphically depicted on the displayunit 14. Thereby, the operation sensation of the user is furtherimproved.

Although the present disclosure is described based on the figures andthe embodiments, it is to be understood that various modifications andchanges may be implemented by those who are ordinarily skilled in theart. Accordingly, such modifications and changes are included in a scopeof the present disclosure. For example, a function and the like includedin each element is rearranged by combining a plurality of elements ordividing the element without logical inconsistency.

For example, it is configured that a tactile sensation is stimulateduntil the load on the touch sensor 11 calculated based on the output ofthe load detection unit 12 or the piezoelectric element 17 satisfies thestandard (for example, 1 N) to provide the tactile sensation and, whenthe load satisfies the standard, the tactile sensation providing unit 13or the piezoelectric element 17 is driven by the predetermined drivesignal to vibrate the touch face 11 a, such that the tactile sensationis stimulated. Thereby, the click sensation is provided to the operatorsuch that the operator recognizes that an input operation is completed.Accordingly, even by the button switch such as the push-button switch(push-type button switch) which is graphically depicted on the touchsensor 11, the operator carries out the input operation to the touchsensor 11 feeling the realistic click sensation similar to that obtainedwhen operating the push-button switch. Thus, the operator may not havethe feeling of strangeness. Moreover, since the operator carries out theinput operation in conjunction with perception to “have pressed” thetouch sensor 11, erroneous inputs caused by mere pressing are prevented.

The standard of the pressure load to provide the tactile sensation maybe appropriately set in accordance with a load characteristic of anintended push-button switch in pressing. For example, the standard maybe set to be equal to a load at which the touch sensor 11 responds tothe touch input (synchronizing a timing to provide the tactile sensationwith a timing of response to the touch input by the touch sensor 11) orto be higher than the load at which the touch sensor 11 responds to thetouch input (setting the timing to provide the tactile sensation laterthan the timing of response to the touch input by the touch sensor 11).For example, when the tactile sensation providing apparatus according tothe present embodiment is applied to a mobile terminal, it is preferableto set the standard equal to or higher than the load at which the touchsensor 11 responds to the touch input (setting the timing to provide thetactile sensation later than the timing of response to the touch inputby the touch sensor 11). Or, the users set the standard as desired, suchthat an elder user may set it heavier (slower) and a young user may setit lighter (quicker).

In addition, for example, the numbers of tactile sensation providingunits 13, load detection units 12 and piezoelectric elements 17 are notlimited to the numbers set forth in the embodiments but may take anynumber. For example, the number of piezoelectric elements 17 is notlimited to three but may take any number. Further, the piezoelectricelement 17 may have a known configuration such as monomorph, unimorph,bimorph and a laminated type, based on a size, vibration amplitude andthe like of the touch sensor 11.

The present disclosure is effectively applicable also to a tactilesensation providing apparatus in which the touch sensor 11 serves as atouch switch for on/off operations. Also, the tactile sensationproviding apparatus according to the present disclosure is capable ofproviding feelings of a multistep switch, such as a two-step switch(pressed further after pressed), by sequentially providing the tactilesensation on different standards (loads) while the touch sensor 11 isbeing pressed. Thereby, if the input apparatus is applied to a releasebutton of a camera, for example, a feeling of lock focus (first step)and a feeling of release (second step) are provided. In addition, incombination with the display unit 14, the input apparatus changes adisplay of a menu level screen and the like in a variety of manners inaccordance with the steps of pressing. Moreover, when providing thefeelings of the multistep switch as described above, the drive signal tovibrate the touch face is changed at each step in order to provide adifferent tactile sensation at each step.

According to the present disclosure, the tactile sensation providingapparatus drives the tactile sensation providing unit 13 or thepiezoelectric unit 17 when the pressure load detected based on theoutput of the load detection unit 12 or the piezoelectric element 17satisfies the standard to provide the tactile sensation. Here, “when thepressure load detected based on the output of the load detection unit 12or the piezoelectric element 17 satisfies the standard to provide thetactile sensation” may represent either “when the pressure load detectedreaches a standard value to provide the tactile sensation”, “when thepressure load detected exceeds the standard value to provide the tactilesensation”, or “when the standard value to provide the tactile sensationis detected based on the output of the load detection unit or thepiezoelectric element”.

REFERENCE SIGNS LIST

-   11 touch sensor-   11 a touch face-   12 load detection unit-   13 tactile sensation providing unit-   14 display unit-   15 memory unit-   16 control unit-   17 piezoelectric element-   21 housing-   22 insulator-   23 upper cover-   24 insulator-   31 load sensor-   32 piezoelectric element

1. A tactile sensation providing apparatus comprising: a touch sensorconfigured to detect a touch input; a load detection unit configured todetect a pressure load on a touch face of the touch sensor; a tactilesensation providing unit configured to vibrate the touch face; and acontrol unit configured to adjust a drive signal of the tactilesensation providing unit based on a pushed position when the pressureload detected by the load detection unit satisfies a standard to providea tactile sensation.
 2. The tactile sensation providing apparatusaccording to claim 1, wherein the control unit controls the tactilesensation providing unit based on adjustment information set for each ofareas in a size corresponding to a position on the touch face such thatthe tactile sensation is provided by vibration with certain amplitude.3. The tactile sensation providing apparatus according to claim 2,wherein the areas to be set with the adjustment information are dividedbased on a position of the tactile sensation providing unit.
 4. Thetactile sensation providing apparatus according to claim 1, wherein thecontrol unit adjusts a voltage to be applied to the tactile sensationproviding unit based on the pushed position such that the tactilesensation providing unit provides the tactile sensation by vibrationwith certain amplitude.
 5. The tactile sensation providing apparatusaccording to claim 1, wherein the control unit adjusts a phase ofvibration of the tactile sensation providing unit based on the pushedposition such that the tactile sensation providing unit provides thetactile sensation by vibration with certain amplitude.
 6. The tactilesensation providing apparatus according to claim 1, wherein the controlunit adjusts the drive signal of the tactile sensation providing unit toprovide the tactile sensation as a click sensation by vibration withcertain amplitude.
 7. A control method for a tactile sensation providingapparatus including a touch sensor configured to detect a touch input, aload detection unit configured to detect a pressure load on a touch faceof the touch sensor, and a tactile sensation providing unit configuredto vibrate the touch face, the control method comprising adjusting adrive signal of the tactile sensation providing unit based on a pushedposition when the pressure load detected by the load detection unitsatisfies a standard to provide a tactile sensation.
 8. A tactilesensation providing apparatus comprising: a touch sensor configured todetect a touch input; a piezoelectric element mounted on the touchsensor; and a control unit configured to detect a pressure load on atouch face of the touch sensor based on an output signal of thepiezoelectric element and, when the pressure load detected satisfies astandard to provide a tactile sensation, to adjust a drive signal of thepiezoelectric element based on a pushed position.
 9. The tactilesensation providing apparatus according to claim 8, wherein the controlunit controls the piezoelectric element based on adjustment informationset for each of areas in a size corresponding to a position on the touchface such that the tactile sensation is provided by vibration withcertain amplitude.
 10. The tactile sensation providing apparatusaccording to claim 9, wherein the areas to be set with the adjustmentinformation are divided based on a position of the piezoelectricelement.
 11. The tactile sensation providing apparatus according toclaim 8, wherein the control unit adjusts a voltage to be applied to thepiezoelectric element based on the pushed position such that thepiezoelectric element provides the tactile sensation by vibration withcertain amplitude.
 12. The tactile sensation providing apparatusaccording to claim 8, wherein the control unit adjusts a phase ofvibration of the piezoelectric element based on the pushed position suchthat the piezoelectric element provides the tactile sensation byvibration with certain amplitude.
 13. The tactile sensation providingapparatus according to claim 8, wherein the control unit adjusts thedrive signal of the piezoelectric element to provide the tactilesensation as a click sensation by the vibration with the certainamplitude.
 14. A control method for a tactile sensation providingapparatus including a touch sensor configured to detect a touch input,and a piezoelectric element mounted on the touch sensor, the controlmethod comprising detecting a pressure load on a touch face of the touchsensor based on an output signal of the piezoelectric element and, whenthe pressure load detected satisfies a standard to provide a tactilesensation, adjusting a drive signal of the piezoelectric element basedon a pushed position.
 15. The tactile sensation providing apparatusaccording to claim 1, wherein the control unit adjusts a parameterassociated with adjustment of the drive signal corresponding to thepushed position based on drive adjustment information when the pressureload detected by the load detection unit satisfies the standard, thedrive adjustment information being indicative of relationship betweenpositions on the touch face and values of the parameter to generatevibration with same amplitude at the respective positions.
 16. Thetactile sensation providing apparatus according to claim 15, wherein theparameter is a voltage, phase, frequency, amplitude, or current of thedrive signal, period during which the drive signal is applied to thetactile sensation providing unit, or time at which the drive signal isapplied to the tactile sensation providing unit.
 17. The tactilesensation providing apparatus according to claim 1, wherein the controlunit applies as the drive signal a triangle wave or a sine wave to thetactile sensation providing unit when a soft tactile sensation is to beprovided, and applies as the drive signal a square wave to the tactilesensation providing unit when a hard tactile sensation is to beprovided.
 18. The tactile sensation providing apparatus according toclaim 1, wherein the control unit applies as the drive signal a sinewave or a square wave to the tactile sensation providing unit when aclick sensation is to be provided.
 19. The tactile sensation providingapparatus according to claim 1, wherein when feelings of a multistepswitch are to be provided, the control unit changes the drive signal ateach step to provide a different tactile sensation at each step.
 20. Thetactile sensation providing apparatus according to claim 8, wherein thecontrol unit adjusts a parameter associated with adjustment of the drivesignal corresponding to the pushed position based on drive adjustmentinformation when the pressure load detected satisfies the standard, thedrive adjustment information being indicative of relationship betweenpositions on the touch face and values of the parameter to generatevibration with same amplitude at the respective positions.